# Too many values to unpack with python

I have a little problem with Python. I'm try to write an application for DCM standard who some slice and draw the final model.

This is my code:

``````from lar import *
from scipy import *
import scipy
import numpy as np
from time import time
from pngstack2array3d import pngstack2array3d

colors = 2
theColors = []
DEBUG = False
MAX_CHAINS = colors

# It is VERY important that the below parameter values
# correspond exactly to each other !!
# ------------------------------------------------------------
MAX_CHUNKS = 75
imageHeight, imageWidth = 250,250  # Dx, Dy

# configuration parameters
# ------------------------------------------------------------

beginImageStack = 430
endImage = beginImageStack
nx = ny =  50
imageDx = imageDy =  50
count = 0

# ------------------------------------------------------------
# Utility toolbox
# ------------------------------------------------------------

def ind(x,y): return x + (nx+1) * (y + (ny+1) )

def invertIndex(nx,ny):
nx,ny = nx+1,ny+1
def invertIndex0(offset):
a0, b0 = offset / nx, offset % nx
a1, b1 = a0 / ny, a0 % ny
return b0,b1
return invertIndex0

def invertPiece(nx,ny):
def invertIndex0(offset):
a0, b0 = offset / nx, offset % nx
a1, b1 = a0 / ny, a0 % ny
return b0,b1
return invertIndex0

# ------------------------------------------------------------
# computation of d-chain generators (d-cells)
# ------------------------------------------------------------

# cubic cell complex
# ------------------------------------------------------------
def the3Dcell(coords):
x,y= coords
return [ind(x,y),ind(x+1,y),ind(x,y+1),ind(x+1,y+1)]

# construction of vertex coordinates (nx * ny )
# ------------------------------------------------------------
V = [[x,y] for y in range(ny+1) for x in range(nx+1) ]

if __name__=="__main__" and DEBUG == True:
print "\nV =", V

# construction of CV relation (nx * ny)
# ------------------------------------------------------------
CV = [the3Dcell([x,y]) for y in range(ny) for x in range(nx)]

if __name__=="__main__" and DEBUG == True:
print "\nCV =", CV
#hpc = EXPLODE(1.2,1.2,1.2)(MKPOLS((V,CV[:500]+CV[-500:])))
#box = SKELETON(1)(BOX([1,2,3])(hpc))
#VIEW(STRUCT([box,hpc]))

# construction of FV relation (nx * ny )
# ------------------------------------------------------------
FV = []
v2coords = invertIndex(nx,ny)
for h in range(len(V)):
x,y= v2coords(h)
if (x < nx) and (y < ny): FV.append([h,ind(x+1,y),ind(x,y+1),ind(x+1,y+1)])

if __name__=="__main__" and DEBUG == True:
print "\nFV =",FV
#hpc = EXPLODE(1.2,1.2,1.2)(MKPOLS((V,FV[:500]+FV[-500:])))
#box = SKELETON(1)(BOX([1,2,3])(hpc))
#VIEW(STRUCT([box,hpc]))

# construction of EV relation (nx * ny )
# ------------------------------------------------------------
EV = []
v2coords = invertIndex(nx,ny)
for h in range(len(V)):
x,y = v2coords(h)
if x < nx: EV.append([h,ind(x+1,y)])
if y < ny: EV.append([h,ind(x,y+1)])

if __name__=="__main__" and DEBUG == True:
print "\nEV =",EV
#hpc = EXPLODE(1.2,1.2,1.2)(MKPOLS((V,EV[:500]+EV[-500:])))
#box = SKELETON(1)(BOX([1,2,3])(hpc))
#VIEW(STRUCT([box,hpc]))

# ------------------------------------------------------------
# computation of boundary operators (∂3 and ∂2s)
# ------------------------------------------------------------

"""
# computation of the 2D boundary complex of the image space
# ------------------------------------------------------------
Fx0V, Ex0V = [],[]  # x == 0
Fx1V, Ex1V = [],[]  # x == nx-1
Fy0V, Ey0V = [],[]  # y == 0
Fy1V, Ey1V = [],[]  # y == ny-1
v2coords = invertIndex(nx,ny)
for h in range(len(V)):
x,y = v2coords(h)

if (y == 0):
if x < nx: Ey0V.append([h,ind(x+1,y)])
if (x < nx):
Fy0V.append([h,ind(x+1,y),ind(x,y)])
elif (y == ny):
if x < nx: Ey1V.append([h,ind(x+1,y)])
if (x < nx):
Fy1V.append([h,ind(x+1,y),ind(x,y)])

if (x == 0):
if y < ny: Ex0V.append([h,ind(x,y+1)])
if (y < ny):
Fx0V.append([h,ind(x,y+1),ind(x,y)])
elif (x == nx):
if y < ny: Ex1V.append([h,ind(x,y+1)])
if (y < ny):
Fx1V.append([h,ind(x,y+1),ind(x,y)])

FbV = Fy0V+Fy1V+Fx0V+Fx1V
EbV = Ey0V+Ey1V+Ex0V+Ex1V
"""

"""
if __name__=="__main__" and DEBUG == True:
hpc = EXPLODE(1.2,1.2,1.2)(MKPOLS((V,FbV)))
VIEW(hpc)
hpc = EXPLODE(1.2,1.2,1.2)(MKPOLS((V,EbV)))
VIEW(hpc)
"""

# computation of the ∂2 operator on the boundary space
# ------------------------------------------------------------
print "start partial_2_b computation"
#partial_2_b = larBoundary(EbV,FbV)
print "end partial_2_b computation"

# computation of ∂3 operator on the image space
# ------------------------------------------------------------
print "start partial_3 computation"
partial_3 = larBoundary(FV,CV)
print "end partial_3 computation"

# ------------------------------------------------------------
# input from volume image (test: 250 x 250 x 250)
# ------------------------------------------------------------
out = []
Nx,Ny = imageHeight/imageDx, imageWidth/imageDx
segFaces = set(["Fy0V","Fy1V","Fx0V","Fx1V"])

for inputIteration in range(imageWidth/imageDx):
startImage = endImage
endImage = startImage + imageDy
xEnd, yEnd = 0,0
theImage,colors,theColors = pngstack2array3d('SLICES2/', startImage, endImage, colors)
print "\ntheColors =",theColors
theColors = theColors.reshape(1,2)
background = max(theColors[0])
foreground = min(theColors[0])
print "\n(background,foreground) =",(background,foreground)

if __name__=="__main__" and DEBUG == True:
print "\nstartImage, endImage =", (startImage, endImage)

for i in range(imageHeight/imageDx):

for j in range(imageWidth/imageDy):

xStart, yStart = i * imageDx, j * imageDy
xEnd, yEnd = xStart+imageDx, yStart+imageDy

image = theImage[:, xStart:xEnd, yStart:yEnd]
nx,ny = image.shape

if __name__=="__main__" and DEBUG == True:
print "\n\tsubimage count =",count
print "\txStart, yStart =", (xStart, yStart)
print "\txEnd, yEnd =", (xEnd, yEnd)
print "\timage.shape",image.shape

# ------------------------------------------------------------
# image elaboration  (chunck: 50 x 50)
# ------------------------------------------------------------

"""
# Computation of (local) boundary to be removed by pieces
# ------------------------------------------------------------

if pieceCoords[0] == 0:  boundaryPlanes += ["Fx0V"]
elif pieceCoords[0] == Nx-1:  boundaryPlanes += ["Fx1V"]
if pieceCoords[1] == 0:  boundaryPlanes += ["Fy0V"]
elif pieceCoords[1] == Ny-1:  boundaryPlanes += ["Fy1V"]

"""
#if __name__=="__main__" and DEBUG == True:
#planesToRemove = list(segFaces.difference(boundaryPlanes))
#FVtoRemove = CAT(map(eval,planesToRemove))

count += 1

# compute a quotient complex of chains with constant field
# ------------------------------------------------------------
chains2D = [[] for k in range(colors)]
def addr(x,y): return x + (nx) * (y + (ny))
for x in range(nx):
for y in range(ny):
if (image[x,y] == background):
chains2D[1].append(addr(x,y))
else:
chains2D[0].append(addr(x,y))

#if __name__=="__main__" and DEBUG == True:
#print "\nchains3D =\n", chains3D

# compute the boundary complex of the quotient cell
# ------------------------------------------------------------
objectBoundaryChain = larBoundaryChain(partial_3,chains2D[1])
b2cells = csrChainToCellList(objectBoundaryChain)
sup_cell_boundary = MKPOLS((V,[FV[f] for f in b2cells]))

# remove the (local) boundary (shared with the piece boundary) from     the quotient cell
# ------------------------------------------------------------

"""
cellIntersection = matrixProduct(csrCreate([FV[f] for f in     b2cells]),csrCreate(FVtoRemove).T)
#print "\ncellIntersection =", cellIntersection
cooCellInt = cellIntersection.tocoo()
b2cells = [cooCellInt.row[k] for k,val in enumerate(cooCellInt.data)     if val >= 4]
"""

# ------------------------------------------------------------
# visualize the generated model
# ------------------------------------------------------------

print "xStart, yStart =", xStart, yStart

if __name__=="__main__":
sup_cell_boundary = MKPOLS((V,[FV[f]  for f in b2cells]))
if sup_cell_boundary != []:
out += [T([1,2])([xStart,yStart])    (STRUCT(sup_cell_boundary))]
if count == MAX_CHUNKS:
VIEW(STRUCT(out))

# ------------------------------------------------------------
# interrupt the cycle of image elaboration
# ------------------------------------------------------------
if count == MAX_CHUNKS: break
if count == MAX_CHUNKS: break
if count == MAX_CHUNKS: break
``````

And this is the error take from the terminal :

``````---------------------------------------------------------------------------
ValueError                                Traceback (most recent call last)
<ipython-input-4-2e498c6090a0> in <module>()
213
214                         image = theImage[:, xStart:xEnd, yStart:yEnd]
--> 215                         nx,ny = image.shape
216
217                         if __name__=="__main__" and DEBUG == True:

ValueError: too many values to unpack
``````

Someone can help me to solve this issue????

-
What is `image.shape` at that point in the code? (Also, it's a bad idea to post hundreds of lines of code to StackOverflow, since most answerers won't want to read through them. Generally it's better to come up with a short, preferably reproducible example that shows your problem) –  David Robinson Jun 12 '13 at 17:54
@DavidRobinson i want to make image as a 2d array, like image = theImage[xStart:xEnd, yStart:yEnd] and do nx, ny = image.shape but it return the same error, too many values to unpack –  Fabio Jun 20 '13 at 14:48

## 1 Answer

Based on the line:

``````image = theImage[:, xStart:xEnd, yStart:yEnd]
``````

`image` is a 3d array, not a 2d array (it appears to be multiple slices of an image), with the 2nd and 3rd dimensions representing `x` and `y` respectively. Thus, if you want to get its dimensions you'll need to unpack it into three dimensions, something like:

``````nslice, nx, ny = image.shape
``````
-
i need to unpack it in two dimension, this is a 2 dimension linear algebric rapresentator for python that show the 2D model of the slice –  Fabio Jun 18 '13 at 14:56